Controlling autonomous vehicles to optimize traffic characteristics

ABSTRACT

Aspects of the disclosure relate to controlling autonomous vehicles to optimize traffic characteristics. A computing platform may receive vehicle guidance data from autonomous vehicle control systems of vehicles. Subsequently, the computing platform may identify a number of the vehicles currently operating in an autonomous mode based on the vehicle guidance data. Thereafter, the computing platform may identify a target number of the vehicles to be operated in an autonomous mode in order to optimize traffic characteristics. Then, the computing platform may generate messages directing selected vehicles to switch into autonomous mode in order to achieve the target number. Subsequently, the computing platform may send the messages directing the selected vehicles to switch into autonomous mode in order to receive incentives. Thereafter, the computing platform may award the incentives to the selected vehicles that switch into the autonomous mode as directed by the messages.

BACKGROUND

Aspects of the disclosure relate to controlling the operation of vehiclecontrol and guidance systems for one or more autonomous vehicles. Inparticular, one or more aspects of the disclosure relate to providingincentives for drivers of autonomous vehicles to adjust autonomousvehicle settings in order to improve one or more trafficcharacteristics.

Autonomous vehicles are becoming increasingly sophisticated as satellitenavigation technologies, traffic and pedestrian sensor technologies, andguidance technologies continue to improve. Despite advances in varioustechnologies, however, it may be difficult to coordinate or otherwisedirect autonomous vehicles to drive effectively together with otherautonomous vehicles and non-autonomous vehicles. For example, differentautonomous vehicles may have different capabilities, and thereforedifferent autonomous vehicles may not coordinate effectively with othervehicles, resulting in decreased traffic characteristics such as safety,traffic flow, and average speed.

SUMMARY

Aspects of the disclosure provide effective, efficient, scalable, andconvenient technical solutions that address and overcome the technicalproblems associated with controlling one or more vehicles includingautonomous vehicles, particularly in instances in which autonomousvehicles are controlled to improve traffic characteristics such assafety, traffic flow, or average speed.

In accordance with one or more embodiments, a computing platform havingat least one processor, a memory, and a communication interface mayreceive, via the communication interface, vehicle guidance dataassociated with vehicles from autonomous vehicle control systems of thevehicles. Subsequently, the computing platform may identify a number ofthe vehicles currently operating in an autonomous mode based on thevehicle guidance data. Thereafter, the computing platform may identify atarget number of the vehicles to be operated in an autonomous mode inorder to optimize one or more traffic characteristics for the vehicles.Then, the computing platform may generate one or more messages directingselected vehicles to switch into autonomous mode in order to achieve thetarget number and/or may generate one or more messages directingselected vehicles to present incentives to switch into autonomous modein order to achieve the target number. Subsequently, the computingplatform may send, via the communication interface, to autonomousvehicle control systems of the selected vehicles, the one or moremessages directing the selected vehicles to switch into autonomous modein order to receive incentives and/or may send the one or more messagesdirecting the selected vehicles to present the incentives to switch intoautonomous mode. Thereafter, the computing platform may award theincentives to the selected vehicles that switch into the autonomous modeas directed by the one or more messages.

In some embodiments, the computing platform may also generate one ormore messages instructing one or more vehicles to present incentives toswitch out of an autonomous mode in order to optimize the trafficcharacteristic. The computing platform may further send the messages tothe one or more vehicles, and award the incentives to the one or morevehicles that switch out of the autonomous mode as directed by themessages.

In some embodiments, the computing platform may also generate one ormore messages instructing one or more vehicles to present incentives tofollow alternate routes in order to optimize the one or more trafficcharacteristics. The computing platform may further send the messages tothe one or more vehicles, and award the incentives to the one or morevehicles that follow alternate routes as directed by the messages.

In some embodiments, the computing platform may receive vehicle guidancedata from non-autonomous vehicles having non-autonomous vehicle controlsystems. The computing platform may further generate one or moremessages instructing one or more non-autonomous vehicles to presentincentives to follow alternate routes in order to optimize the one ormore traffic characteristics. The computing platform may further sendthe messages to the one or more non-autonomous vehicles, and award theincentives to the one or more non-autonomous vehicles that followalternate routes as directed by the messages.

In some embodiments, the computing platform may cause a portion of anincentive to be awarded based on a determination that a vehicle onlypartially complied with the incentive. The determination may comprisedetermining that the vehicle followed a portion of an alternate route,switched out an autonomous mode after accepting an incentive to switchinto the autonomous mode, or switched into an autonomous mode afteraccepting an incentive to switch out of the autonomous mode.

In some embodiments, the computing platform identifies the target numberof vehicles based on one or more of the actual number of vehiclescurrently operating in autonomous mode, driver information correspondingto one or more drivers of the vehicles, vehicle informationcorresponding to the vehicles, and road conditions corresponding to oneor more roads associated with the vehicles.

In some embodiments, an amount of the incentive is based on one or moreof a driver score associated with a driver of a vehicle and a vehiclescore associated with the vehicle. These features, along with manyothers, are discussed in greater detail below.

BRIEF DESCRIPTION OF THE DRAWINGS

The present disclosure is illustrated by way of example and not limitedin the accompanying figures in which like reference numerals indicatesimilar elements and in which:

FIGS. 1A-1D depict an illustrative operating environment for controllingone or more autonomous vehicles to optimize traffic characteristics inaccordance with one or more example embodiments;

FIGS. 2A-2E depict an illustrative event sequence for controlling one ormore autonomous vehicles to optimize traffic characteristics inaccordance with one or more example embodiments;

FIGS. 3 & 4 depict example graphical user interfaces for registeringvehicles to a computing platform in accordance with one or more exampleembodiments;

FIG. 5 depicts an illustrative group of vehicles that may be controlledin accordance with one or more example embodiments;

FIGS. 6 & 7 depict example graphical user interfaces for acceptingincentives to adjust settings of vehicles to optimize a trafficcharacteristic in accordance with one or more example embodiments; and

FIG. 8 depicts an illustrative method for controlling groups ofautonomous vehicles to optimize traffic characteristics in accordancewith one or more example embodiments.

DETAILED DESCRIPTION

In the following description of various illustrative embodiments,reference is made to the accompanying drawings, which form a parthereof, and in which is shown, by way of illustration, variousembodiments in which aspects of the disclosure may be practiced. It isto be understood that other embodiments may be utilized, and structuraland functional modifications may be made, without departing from thescope of the present disclosure. Various connections between elementsare discussed in the following description. It is noted that theseconnections are general and, unless specified otherwise, may be director indirect, wired or wireless, and that the specification is notintended to be limiting in this respect.

Some aspects of the disclosure relate to controlling one or moreautonomous vehicles and/or managing one or more other vehicles tooptimize traffic characteristics for the one or more vehicles. In someaspects, traffic characteristics include traffic safety, traffic flow,traffic average speed, traffic maximum speed, or any other trafficcharacteristics. Traffic characteristics may be optimized by analyzingdata related to multiple vehicles in traffic and identifying adjustmentsthat individual vehicles can make to optimize the selected trafficcharacteristics.

In some embodiments, causing vehicles to switch into or out of anautonomous mode may optimize one or more traffic characteristics. Insome situations, a vehicle in autonomous mode may perform better than adriver with regard to certain traffic characteristics. In othersituations, a vehicle in autonomous mode may perform worse than a driverwith regard to certain traffic characteristics. By identifying thesesituations and instructing and/or otherwise causing select vehicles tochange into or out of an autonomous mode, the traffic characteristicsmay be optimized.

In some situations, autonomous vehicles may perform better than driversof a given skill level. Accordingly, optimizing a traffic characteristicmay include identifying the skill level of an individual driver and/or agroup of drivers. Driver scores may be evaluated using information aboutthe driver(s) such as demographic information, driving history data,tickets received by the driver, accident history data, or any otherinformation characterizing the driver. In some situations, traffic maybe optimized by causing drivers with low driver scores to change intoautonomous mode and/or by causing drivers with high driver scores tochange out of autonomous mode.

In some situations, certain vehicles may perform better when driven inautonomous mode than a driver, whereas other vehicles may perform betterwhen driven in a non-autonomous mode. Accordingly, optimizing a trafficcharacteristic may include calculating and/or otherwise determining avehicle score for an individual vehicle or a group of vehicles. Avehicle score may be calculated and/or otherwise determined usinginformation about the vehicle(s) including autonomous mode effectivenessratings for a given vehicle. Such effectiveness ratings may include, forexample, a safety rating of an autonomous mode for a certain vehicle.The safety rating may be calculated and/or otherwise determined based ona number and/or type of sensors used by the autonomous mode, an accidenthistory of the vehicle or vehicles with the same make and/or model whendriven in autonomous mode, and/or any other data characterizing thesafety of the vehicle when driven in autonomous mode. Othereffectiveness ratings may be calculated and/or otherwise determinedbased on similar data characterizing effectiveness for other trafficcharacteristics, such as traffic flow. Vehicles scores may additionallyor alternatively be calculated and/or otherwise determined based onmaintenance data for the vehicle, crash safety ratings of the vehicle,capabilities of the vehicle, or any other data characterizing theeffectiveness of the vehicle for a given traffic characteristic.Accordingly, in some situations, traffic may be optimized by causingvehicles with high effectiveness scores to change into autonomous modeand/or by causing vehicles with low effectiveness scores to change outof autonomous mode.

In some situations, certain vehicles may perform better when driven inautonomous mode during certain weather conditions, when driven on roadsof a certain type (e.g., urban vs. rural, local vs. highway, etc.), whendriven on roads with certain lane widths, or otherwise depending on roadconditions. Accordingly, optimizing a traffic characteristic may includeidentifying and/or otherwise determining one or more road conditions ofroads associated with a driver or group of drivers. In some situations,traffic may be optimized by causing vehicles driving in certain roadconditions to change into or out of autonomous mode.

In some situations, certain vehicles may perform better when driven inautonomous mode when a certain number, or a certain percentage, of othervehicles are being driving in autonomous mode. Accordingly, optimizing atraffic characteristic may include identifying a number of vehiclesbeing driven in an autonomous mode, and switching one or more vehiclesinto or out of autonomous mode based on the number or percentage ofvehicles being driven in an autonomous mode.

In some situations, optimizing a traffic characteristic may includeidentifying a target number of vehicles for driving in autonomous modebased on one or more conditions, including driver scores, vehiclescores, road conditions, and a number of vehicles being driven in anautonomous mode. In some situations, after identifying a target numberof vehicles for driving in autonomous mode, traffic may be optimized bycausing one or more vehicles to switch into or out of autonomous mode inorder to achieve the target number.

In some situations, incentives may be provided to encourage drivers toallow their vehicles to be adjusted into or out of an autonomous mode.In some situations, incentives may include free or discounted goods orservices such as free tolls, discounted access to priority lanes,discounts on vehicle insurance, and the like. In some situations,incentives may include modifications to traffic control, such asallocating autonomous-only roads or lanes, allowing a higher speed limitfor a vehicle or a group of vehicles, adjusting timing of trafficlights, and the like.

In some situations, messages containing incentive information may besent to selected drivers. The messages may be displayed on a display ofthe driver's vehicle or smart device. In some situations, drivers mayaccept or decline the incentive. In some situations, vehicle controlsystems may automatically accept or decline the incentive. In somesituations, when the incentive is accepted, the driver's vehicle mayautomatically be adjusted into or out of an autonomous mode asinstructed by the message. Drivers may be awarded the incentives afteraccepting the incentives.

In some situations, a driver's compliance with an accepted incentive maybe monitored. For example, a driver may switch back out of an autonomousmode shortly after accepting an incentive to switch into an autonomousmode. In some situations, a driver may be awarded a partial incentivebased on a length of time or a distance driven in compliance with theincentive.

In some situations, traffic characteristics may additionally oralternatively be optimized by selecting alternate routes for one or morevehicles. Accordingly, in some situations, one or more vehicles may beoffered incentives to follow alternate routes. Vehicles may be monitoredand awarded incentives when they follow the alternate routes. In somesituations, vehicles that only follow part of an alternate route mayreceive a partial incentive. In some situations, non-autonomous vehiclesmay be offered incentives to follow alternate routes.

FIGS. 1A, 1B, 1C, and 1D depict an illustrative operating environmentfor controlling one or more autonomous vehicles to optimize trafficcharacteristics in accordance with one or more example embodiments.Referring to FIG. 1A, operating environment 100 may include a vehiclemanagement computing platform 110, a road conditions monitoring system120, a vehicle routing system 130, a driver information system 140, avehicle information system 145, an autonomous vehicle control system150, an autonomous vehicle control system 160, and a non-autonomousvehicle control system 170. In one or more arrangements, vehiclemanagement computing platform 110, road conditions monitoring system120, vehicle routing system 130, driver information system 140, vehicleinformation system 145, autonomous vehicle control system 150,autonomous vehicle control system 160, and non-autonomous vehiclecontrol system 170 may be connected by network 190, which may includeone or more wired networks and/or one or more wireless networks. Inaddition, each of vehicle management computing platform 110, roadconditions monitoring system 120, vehicle routing system 130, driverinformation system 140, vehicle information system 145, autonomousvehicle control system 150, autonomous vehicle control system 160, andnon-autonomous vehicle control system 170 may be special purposecomputing devices configured to perform specific functions, asillustrated in greater detail below, and may include specific computingcomponents such as processors, memories, communication interfaces,and/or the like.

For example, vehicle management computing platform 110 may be configuredto manage and control a group of autonomous and non-autonomous vehiclesto optimize traffic characteristics such as safety and/or traffic flow,as illustrated in greater detail below. Road conditions monitoringsystem 120 may be configured to collect, serve, and/or otherwise providedata about road and weather conditions, such as road speed limits, lanewidth, accident history for a road, current weather along a road, andweather forecasts for a road. Vehicle routing system 130 may beconfigured to generate routes for navigating between an origin and adestination. Driver information system 140 may be configured to collectand provide information about drivers, including demographics data,accident history, and driving habits. Vehicle information system 145 maybe configured to collect, serve, and/or otherwise provide informationabout vehicles, including vehicle capabilities, autonomous capabilities,and service history.

Autonomous vehicle control systems 150, 160 may be configured to monitorand/or send vehicle guidance data (which may include, e.g., speed data,position data, destination data, and operating status of autonomousmode) associated with corresponding autonomous vehicles to vehiclemanagement computing platform 110 and/or one or more other computingdevices included in operating environment 100. Autonomous vehiclecontrol systems 150, 160 may be further configured to controlcorresponding autonomous vehicles based on commands and/or otherinformation received from vehicle management computing platform 110and/or one or more other computing devices included in operatingenvironment 100.

Non-autonomous vehicle control system 170 may be configured to monitorand/or send vehicle guidance data (which may include, e.g., speed data,position data, and destination data) associated with a correspondingnon-autonomous vehicle to vehicle management computing platform 110and/or one or more other computing devices included in operatingenvironment 100. In addition, non-autonomous vehicle control system 170may be further configured to display one or more user interfaces. Forexample, non-autonomous vehicle control system 170 may be configured todisplay one or more user interfaces for responding to messages receivedfrom vehicle management computing platform 110 and/or one or more othercomputing devices included in operating environment 100.

Referring to FIG. 1B, vehicle management computing platform 110 mayinclude a processor 111, memory 112, and a communication interface 115.Processor 111 may control operations of vehicle management computingplatform 110, and memory 112 may store instructions that, when executedby processor 111, cause vehicle management computing platform 110 toperform one or more functions. Communication interface 115 may includeone or more wired and/or wireless network interfaces, and communicationinterface 115 may connect vehicle management computing platform 110 toone or more networks (e.g., network 190) and/or enable vehiclemanagement computing platform 110 to exchange information and/orotherwise communicate with one or more devices connected to suchnetworks. Memory 112 may store and/or otherwise provide a vehiclemanagement module 113 and a vehicle management database 114. Vehiclemanagement module 113 may store instructions that, when executed byprocessor 111, cause vehicle management computing platform 110 to manageone or more autonomous vehicles to optimize traffic characteristics,offer incentives, and/or perform one or more other functions. Vehiclemanagement database 114 may store information that may be used byvehicle management computing platform 110 in controlling autonomousvehicles to optimize traffic characteristics and/or in performing one ormore other functions.

Referring to FIG. 1C, autonomous vehicle control system 150 may includea processor 151, memory 152, and a communication interface 155.Processor 151 may control operations of autonomous vehicle controlsystem 150, and memory 152 may store instructions that, when executed byprocessor 151, cause autonomous vehicle control system 150 to performone or more functions. Communication interface 155 may include one ormore wired and/or wireless network interfaces, and communicationinterface 155 may connect autonomous vehicle control system 150 to oneor more networks (e.g., network 190) and/or enable autonomous vehiclecontrol system 150 to exchange information and/or otherwise communicatewith one or more devices connected to such networks. Memory 152 maystore and/or otherwise provide a vehicle control module 153 and avehicle control database 154. Vehicle control module 153 may storeinstructions that, when executed by processor 151, cause autonomousvehicle control system 150 to monitor and/or control an autonomousvehicle in which autonomous vehicle control system 150 may be installedand/or perform one or more other functions. Vehicle control database 154may store information that may be used by autonomous vehicle controlsystem 150 in monitoring and/or controlling an autonomous vehicle inwhich autonomous vehicle control system 150 may be installed and/or inperforming one or more other functions.

Autonomous vehicle control system 150 also may include a display 156,sensors 157, a local device interface 158, and a vehicle controlinterface 159. Display 156 may display one or more user interfaces to adriver and/or passengers of the vehicle containing autonomous vehiclecontrol system 150. Display 156 may accept input (e.g., via atouchscreen interface) or be associated with one or more user interfacesthat accept input related to the displayed user interfaces. Sensors 157may sense conditions associated with an autonomous vehicle in whichautonomous vehicle control system 150 may be installed and may outputanalog signal data and/or digital signal data to autonomous vehiclecontrol system 150. Such data may include engine data, performance data,navigation data, position data, speed data, and/or other vehicle data.Local device interface 158 may include one or more wired and/or wirelesscommunication interfaces and may, for example, enable autonomous vehiclecontrol system 150 to exchange information with and/or otherwisecommunicate with one or more devices that may be located inside of,close to, and/or within a predetermined distance of an autonomousvehicle in which autonomous vehicle control system 150 may be installed.For example, local device interface 158 may enable autonomous vehiclecontrol system 150 to communicate with one or more smart phones, tabletcomputers, and/or other mobile computing devices that may be used byand/or otherwise associated with a driver of and/or one or morepassengers of an autonomous vehicle in which autonomous vehicle controlsystem 150 may be installed. Vehicle control interface 159 may includeone or more wired and/or wireless communication interfaces and may, forexample, enable autonomous vehicle control system 150 to exchangeinformation with and/or otherwise communicate with one or more devicesand/or components of an autonomous vehicle in which autonomous vehiclecontrol system 150 may be installed so as to direct and/or control theautonomous vehicle in which autonomous vehicle control system 150 may beinstalled. For example, vehicle control interface 159 may enableautonomous vehicle control system 150 to accelerate and/or deceleratethe autonomous vehicle in which autonomous vehicle control system 150may be installed, steer the autonomous vehicle in which autonomousvehicle control system 150 may be installed, direct the autonomousvehicle in which autonomous vehicle control system 150 may be installedto one or more specific locations, drive the autonomous vehicle in whichautonomous vehicle control system 150 may be installed, and/or otherwisecontrol operations of the autonomous vehicle in which autonomous vehiclecontrol system 150 may be installed.

Referring to FIG. 1D, non-autonomous vehicle control system 170 mayinclude a processor 171, memory 172, and a communication interface 175.Processor 171 may control operations of non-autonomous vehicle controlsystem 170, and memory 172 may store instructions that, when executed byprocessor 171, cause non-autonomous vehicle control system 170 toperform one or more functions. Communication interface 175 may includeone or more wired and/or wireless network interfaces, and communicationinterface 175 may connect non-autonomous vehicle control system 170 toone or more networks (e.g., network 190) and/or enable non-autonomousvehicle control system 170 to exchange information and/or otherwisecommunicate with one or more devices connected to such networks. Memory172 may store and/or otherwise provide a vehicle control module 173 anda vehicle control database 174. Vehicle control module 173 may storeinstructions that, when executed by processor 171, cause non-autonomousvehicle control system 170 to control one or more functions of a vehiclein which non-autonomous vehicle control system 170 may be installed.Vehicle control database 174 may store information that may be used bynon-autonomous vehicle control system 170 in controlling functions of avehicle in which non-autonomous vehicle control system 170 may beinstalled and/or in performing one or more other functions.Non-autonomous vehicle control system 170 also may include a display176, sensors 177, and a local device interface 178. Display 176 maydisplay one or more user interfaces to a driver and/or passengers of thevehicle containing non-autonomous vehicle control system 170. Display176 may accept input (e.g., via a touchscreen interface) or beassociated with one or more user interfaces that accept input related tothe displayed user interfaces. Sensors 177 may sense conditionsassociated with a vehicle in which non-autonomous vehicle control system170 may be installed and may output analog signal data and/or digitalsignal data to non-autonomous vehicle control system 170. Such data mayinclude engine data, performance data, navigation data, position data,speed data, and/or other vehicle data. Local device interface 178 mayinclude one or more wired and/or wireless communication interfaces andmay, for example, enable non-autonomous vehicle control system 170 toexchange information with and/or otherwise communicate with one or moredevices that may be located inside of, close to, and/or within apredetermined distance of a vehicle in which non-autonomous vehiclecontrol system 170 may be installed. For example, local device interface178 may enable non-autonomous vehicle control system 170 to communicatewith one or more smart phones, tablet computers, and/or other mobilecomputing devices that may be used by and/or otherwise associated with adriver of and/or one or more passengers of a vehicle in whichnon-autonomous vehicle control system 170 may be installed.

FIGS. 2A, 2B, 2C, 2D, and 2E depict an illustrative event sequence forcontrolling one or more autonomous vehicles to optimize trafficcharacteristics in accordance with one or more example embodiments.Referring to FIG. 2A, at step 201, vehicle management computing platform110 may receive (e.g., via communication interface 115) a registrationrequest from autonomous vehicle control system 150. Autonomous vehiclecontrol system 150 may send the registration request (e.g., viacommunication interface 155) at particular times, locations, uponinstructions of an operator of a vehicle associated with autonomousvehicle control system 150, or in response to some other trigger. Forexample, autonomous vehicle control system 150 may send a registrationrequest to a vehicle management computing platform 110 associated with atoll authority when the vehicle containing autonomous vehicle controlsystem 150 enters a toll road. As another example, autonomous vehiclecontrol system 150 may send a registration request to a vehiclemanagement computing platform 110 associated with a local governmentwhen the vehicle containing autonomous vehicle control system 150 entersan area of the local government (e.g., a state, town, or country). Asyet another example, autonomous vehicle control system 150 may send aregistration request to a vehicle management computing platform 110associated with an insurance company when the vehicle containingautonomous vehicle control system 150 is configured to be controlled bythe vehicle management computing platform 110 associated with theinsurance company. Registration may be initiated by autonomous vehiclecontrol system 150 itself, by autonomous vehicle control system 150 inresponse to one or more directions received from another device (e.g.,vehicle management computing platform 110), or in response to one ormore directions received from a vehicle user (e.g., a driver orpassenger of the vehicle). Registration requests may also be received atvehicle management computing platform 110 from other vehicles, such asvehicles containing autonomous vehicle control system 160 ornon-autonomous vehicle control system 170.

The registration request may include information such as a vehicleidentifier, a driver identifier, an account identifier, a password, orany other registration information. Vehicle management computingplatform 110 may generate one or more graphical user interfaces fortransmission to and display by autonomous vehicle control system 150(e.g., via display 156) by which an operator of the vehicle containingautonomous vehicle control system 150 may enter or confirm theregistration information. For example, as depicted at FIGS. 3-4, agraphical user interface 300, 400 displayed via display 156 may includefields such as “Vehicle ID” and “Driver Name” for entering or confirmingsuch identifiers. In some embodiments, the fields may be auto-populatedby autonomous vehicle control system 150 using data stored in vehiclecontrol database 154. Graphical user interfaces 300, 400 may betransmitted to and/or displayed automatically by autonomous vehiclecontrol system 150 in certain situations, such as when a vehiclecontaining autonomous vehicle control system 150 is started, when avehicle containing autonomous vehicle control system 150 enters a tollroad, when a vehicle containing autonomous vehicle control system 150crosses a border, and the like. Graphical user interfaces 300, 400 maycomprise a selector that causes the registration request to be sent byautonomous vehicle control system 150 to vehicle management computingplatform 110 (e.g., the illustrated “accept” button). In some examples,the registration request is transmitted automatically by autonomousvehicle control system 150 without generating a graphical user interfaceand/or receiving confirmation from an operator of the vehicle containingautonomous vehicle control system 150.

At step 202, vehicle management computing platform 110 may send arequest for additional information about the vehicle and/or driveridentified in the registration request to driver information system 140.In embodiments, the request may contain one or more identifiers of thedriver and/or vehicle. In some embodiments, separate requests may besent to a driver information system 140 and a vehicle information system145 for respectively retrieving information about the driver andvehicle. In other embodiments, the driver information system 140 and/orthe vehicle information system 145 may provide information about boththe driver and the vehicle, so only one request may be sent asillustrated.

At step 203, the vehicle management computing platform 110 receives andprocesses (e.g., by processor 111 executing vehicle management module113) driver information and/or vehicle information associated with thedriver and/or vehicle from driver information system 140 and/or vehicleinformation system 145. The driver information may include an accidenthistory for the driver, demographics data about the driver, drivinghabits of the driver, insurance information associated with the driver,a safety rating for the driver, or any other information about thedriver of the vehicle. The vehicle information may include make/model ofthe vehicle, capabilities of the vehicle (e.g., stopping distance,engine size), maintenance information (e.g., last oil change, last tirechange), autonomous capabilities of the vehicle (e.g., number and typeof sensors), insurance information associated with the vehicle, a safetyrating for the vehicle, or any other vehicle information. Vehiclemanagement computing platform 110 may process the received information,for example, in order to calculate and/or otherwise determine a driversafety score and/or a vehicle safety score.

At step 204, vehicle management computing platform 110 may receive andprocess (e.g., by processor 111 executing vehicle management module 113)vehicle guidance data from autonomous vehicle control system 150 on anongoing basis. Vehicle management computing platform 110 may receive thevehicle guidance data continually, periodically, or by request ofvehicle management computing platform 110. The vehicle guidance data mayinclude speed data, position data, destination data, operating status ofan autonomous mode of the autonomous vehicle control system 150, andother such data related to navigation of the vehicle containing theautonomous vehicle control system 150. Vehicle management computingplatform 110 may further process the data to calculate and/or otherwisedetermine additional information not contained in the vehicle guidanceinformation. For example, vehicle management computing platform 110 mayanalyze position data contained within the vehicle guidance data toderive speed or direction data when vehicle guidance data does notcontain such data. Vehicle management computing platform 110 may furtherestimate data such as destination data based on the vehicle guidancedata and/or other data. For example, vehicle management computingplatform 110 may estimate a destination for a vehicle based onhistorical data (e.g., driving habits data indicating frequent routesfor a driver and/or vehicle, which may be contained in driver/vehicleinformation). As another example, vehicle management computing platform110 may estimate a destination based on a time of day and/or event(e.g., if the vehicle is driving towards a football stadium before agame is about to start).

Steps 201-204 may be repeated with respect to autonomous vehicle controlsystem 160, non-autonomous vehicle control system 170, and othervehicles containing vehicle control systems that register with vehiclemanagement computing platform 110. Vehicle management computing platform110 may receive similar data from non-autonomous vehicle control system170 as from autonomous vehicle control system 150, 160. For example,vehicle management computing platform 110 may receive driverinformation, vehicle information, and vehicle guidance data associatedwith non-autonomous vehicle control system 170, but such informationand/or data may indicate that non-autonomous vehicle control system 170lacks an autonomous mode or otherwise is not configured for autonomousoperation.

Referring to FIG. 2B, at step 205, vehicle management computing platform110 defines (e.g., by processor 111 executing vehicle management module113) an evaluation group of vehicles for which to optimize the trafficcharacteristic. In some embodiments, in defining the evaluation group ofvehicles, vehicle management computing platform 110 may select allregistered vehicles within a certain area or on a certain road. In otherembodiments, in defining the evaluation group of vehicles, vehiclemanagement computing platform 110 may select groups of vehicles that areclose together (e.g., in a cluster on the road and/or otherwise within acertain distance of each other). Referring to FIG. 5, five vehicles 505,510, 515, 520, 525 may be registered to vehicle management computingplatform 110 in a certain area. Any given area may be used, includinglarge areas such as a municipality or state. In some embodiments, areasmay be defined in terms of roads such that, for example, a certainstretch of a highway may define an area. In some embodiments, vehiclemanagement computing platform 110 may define an evaluation groupcontaining vehicles 505, 510, 515, 520, 525 because they are all in agiven area or on a given road. Accordingly, vehicle guidance data suchas location may be used by vehicle management computing platform 110 todefine an evaluation group of vehicles.

In some embodiments, the evaluation group may be defined to includevehicles traveling together through one or more areas. For example,vehicle management computing platform 110 may include vehicles 505, 510,515, 520 in a first group because they are traveling together in thesame direction, and may further include vehicle 525 in a separate groupof vehicles traveling in the other direction. Accordingly, vehiclemanagement computing platform 110 may use a direction or destination ofvehicles to define a group of vehicles in some instances. Vehiclemanagement computing platform 110 may identify and/or otherwisedetermine the direction of vehicles based on vehicle guidance dataindicating the direction, location, or destination of vehicles.

In some embodiments, vehicle management computing platform 110 maydefine evaluation groups based on speed(s) of the vehicles. For example,if vehicles 505, 510, 515 are driving about 80 miles per hour, butvehicle 520 is only driving about 60 miles per hour, vehicles 505, 510,515 may be included in one evaluation group and vehicle 520 may beincluded in another evaluation group. Accordingly, vehicle managementcomputing platform 110 may use vehicle guidance data including speed todefine an evaluation group of vehicles in some instances. In someembodiments, vehicle management computing platform 110 may defineevaluation groups based on destination. For example, if vehicle guidancedata indicates that vehicles 510, 515 will turn left at an upcoming forkin the road, and vehicles 505, 520 will turn right at an upcoming forkin the road, the vehicles may be included in separate evaluation groups.Accordingly, vehicle management computing platform 110 may use vehicleguidance data including destination to define an evaluation group ofvehicles in some instances.

In some instances, vehicle management computing platform 110 may defineevaluation groups of vehicles based on several factors includinglocation, direction, speed, and destination of one or more vehicles.Processor 111, executing vehicle management module 113 of vehiclemanagement computing platform 110, may retrieve, process, and orcalculate one or more of such factors and input the factors intoalgorithms that define one or more evaluation groups of vehiclesregistered to vehicle management computing platform 110. Such algorithmsmay be implemented as part of vehicle management module 113. Suchalgorithms may include rules-based algorithms, supervised orunsupervised learning algorithms, clustering algorithms, neuralnetworks, and/or other such algorithms.

At step 206, vehicle management computing platform 110 generates (e.g.,by processor 111 executing vehicle management module 113) and sends(e.g., via communication interface 115) a query to road conditionsmonitoring system 120. Vehicle management computing platform 110 maysend one or more queries requesting conditions for one or more roadswithin an area corresponding to the evaluation group. The vehiclemanagement computing platform 110 may request road conditionsinformation corresponding to one or more areas associated with theevaluation group. The query or queries may request road conditionsinformation for roads the vehicles are currently driving on and/or roadsthe vehicles may be driving on in the future.

At step 207, vehicle management computing platform 110 receives (e.g.,via communication interface 115) and processes (e.g., by processor 111executing vehicle management module 113) the requested road conditionsinformation. Vehicle management computing platform 110 may receive roadconditions information comprising dynamic information such as weather,precipitation, construction, lane closures, current accidents, currenttraffic levels, accident history, etc. Vehicle management computingplatform 110 may further receive road conditions information comprisingstatic information such as number of lanes, lane width, speed limit,tolls, presence of autonomous-only lanes, etc. Vehicle managementcomputing platform 110 may further process the road conditionsinformation for the one or more roads to calculate and/or otherwisedetermine additional information such as a road safety score, a roadcongestion score, or a road-autonomous score (e.g., a score indicatingthe suitability of the road for autonomous vehicles given static and/ordynamic conditions of the road).

At step 208, vehicle management computing platform 110 identifies (e.g.,by processor 111 executing vehicle management module 113) the number ofvehicles in the evaluation group driving in autonomous mode. Vehiclemanagement computing platform 110 may identify whether each vehicle isdriving in autonomous mode based on the vehicle guidance received fromeach vehicle in step 204. Vehicle management computing platform 110 maycheck the most recently received vehicle guidance data for each vehiclein order to identify whether each vehicle is currently in an autonomousmode.

Referring to FIG. 2C, at step 209, vehicle management computing platform110 identifies (e.g., by processor 111 executing vehicle managementmodule 113) a target number of vehicles for operating in autonomous modein order to optimize one or more traffic characteristics. The one ormore traffic characteristics may, in some embodiments, be one or more ofsafety, traffic flow, traffic average speed, traffic maximum speed, andthe like. Vehicle management computing platform 110 may identify thetarget number of vehicles for operating in autonomous mode usingfeatures extracted from and/or based on one or more of driver and/orvehicle information, vehicle guidance data, road conditions information,and the number of vehicles currently in autonomous mode. Vehiclemanagement computing platform 110 may input such features into one ormore machine learning models (which may, e.g., be maintained and/orexecuted by vehicle management computing platform 110), such asclassifiers, support vector machines, decision trees, neural networks,and other supervised or unsupervised learning models.

The features for inputting into the machine learning models may tend toindicate that a certain ideal number or percentage, or a certain delta(e.g., number or percentage change) of vehicles should be operated inautonomous mode based on values of one or more of the features alone orin combination with other features. For example, a narrow lane width maytend to indicate that more vehicles should be driven in autonomous mode,except when the weather is snowy or rainy. As another example, acongested road may tend to indicate that more vehicles should be drivenin autonomous mode, except when a history of accidents along the roadindicates that several autonomous vehicles were involved in accidentsalong the road. The features may characterize one or more drivers orgroups of drivers in the evaluation group, one or more vehicles orgroups of vehicles in the evaluation group, road conditions of roadsassociated with the evaluation group, and/or a number of vehicles beingdriven in an autonomous mode. Exemplary features may include averagedriver scores for the drivers of the evaluation group, average vehiclesafety scores for the vehicles of the evaluation group, a road safetyscore, a road-autonomous score, and a road congestion score.

Accordingly, the machine learning models (which may, e.g., be maintainedand/or executed by vehicle management computing platform 110) may betrained using a training set of data including multiple data pointshaving feature vectors including the various input features as well asoutcome data for the desired traffic characteristic (e.g., accidenthistory data for a safety characteristic, historic traffic flow data fora traffic flow characteristic, historic average speed data for a trafficaverage speed characteristic, historic maximum speed data for a trafficmaximum speed characteristic, etc.). In some embodiments, a machinelearning model (which may, e.g., be maintained and/or executed byvehicle management computing platform 110) may be trained for each ofmultiple traffic characteristics. In other embodiments, one or moremachine learning models (which may, e.g., be maintained and/or executedby vehicle management computing platform 110) may be trained to eachoptimize multiple traffic characteristics.

After inputting the features for the current evaluation group ofvehicles into the one or more machine learning models, vehiclemanagement computing platform 110 may identify the target number ofvehicles for operating in autonomous mode based on the output of themachine learning models. Each of the one or more models may output anindication of an ideal number, percentage, or change in the number orpercentage of vehicles operating in autonomous mode. Vehicle managementcomputing platform 110 may select an output of one model or combinemultiple outputs from multiple models (e.g., using an average, aweighted average, a median, a mode, or some other combined value) toidentify the target number.

At step 210, vehicle management computing platform 110 selects (e.g., byprocessor 111 executing vehicle management module 113) one or morevehicles of the evaluation group to adjust into or out of autonomousmode based on the difference between the actual number of vehicles inautonomous mode identified in step 208 and the ideal number of vehiclesin autonomous mode identified in step 209. Vehicle management computingplatform 110 may select vehicles from the evaluation group to controlbased on one or more factors associated with the vehicle, such asdriver/vehicle information, vehicle guidance data for the vehicle, androad conditions information. For example, vehicle management computingplatform 110 may select the vehicle or vehicles from the evaluationgroup having the lowest driver safety scores to change into anautonomous mode when the ideal number of vehicles in autonomous mode isless than the actual number of vehicles in autonomous mode. Conversely,vehicle management computing platform 110 may select the vehicle orvehicles from the evaluation group having the highest driver safetyscores to change out of an autonomous mode when the ideal number ofvehicles in autonomous mode is greater than the actual number ofvehicles in autonomous mode. As another example, vehicle managementcomputing platform 110 may identify that a driver of one of the vehicleshas an accident history indicating several accidents in snowy weatherconditions, and that the road conditions are currently snowy, andaccordingly select that vehicle to adjust into an autonomous mode.Vehicle management computing platform 110 may further select somevehicles of the evaluation group to adjust into autonomous mode whilealso selecting other vehicles of the evaluation group to adjust out ofautonomous mode.

At step 211, vehicle management computing platform 110 may optionallysend (e.g., via communication interface 115) one or more requests foralternate routes for the vehicles selected in step 210 and/or for all orsome of the vehicles of the evaluation group. Such requests may containinformation about the location, destination, and/or current route ofeach such vehicle. Vehicle routing system 130 receives and processes therequests in order to identify alternate routes from each vehicle'scurrent location to the same vehicle's destination. In some embodiments,vehicle routing system 130 may find a defined number of alternate routesfor each vehicle. In other embodiments, vehicle routing system 130 mayfind only routes that decrease a projected travel time for a vehicle. Insome embodiments, vehicle routing system 130 may find routes thatincrease a travel time by less than a threshold amount of time. At step212, vehicle management computing platform 110 may receive (e.g., viacommunication interface 115) the alternate routes.

Referring to FIG. 2D, at step 213, vehicle management computing platform110 may evaluate (e.g., by processor 111 executing vehicle managementmodule 113) each alternate route for each vehicle in order to evaluateand/or otherwise determine whether it should recommend an alternateroute for the vehicle. If necessary, vehicle management computingplatform 110 may send one or more requests to road conditions monitoringsystem 120 to receive road conditions information for roads of thealternate routes. Based on the road conditions information, thedriver/vehicle information, and/or the vehicle guidance data for eachvehicle and route, vehicle management computing platform 110 may selectone or more alternate routes to recommend to the one or more vehicles.For example, when vehicle management computing platform 110 isoptimizing a safety characteristic of traffic, it may identify alternateroutes that are safer than the current route of a vehicle, and recommendthe safest alternate route. As another example, when vehicle managementcomputing platform 110 is optimizing a traffic flow characteristic, itmay identify alternate routes that are less congested than the currentroute of the vehicle and recommend the fastest and/or least congestedalternate route. Accordingly, the vehicle management computing platform110 may further optimize one or more traffic characteristics byrecommending alternate routes.

Although only vehicles having an autonomous vehicle control system 150,160 may be selected for adjustment into or out of autonomous mode atstep 210, both vehicles having an autonomous vehicle control system 150,160 and vehicles having a non-autonomous vehicle control system 170 maybe evaluated (e.g., by vehicle management computing platform 110) forroute adjustments at step 213. Accordingly, vehicle management computingplatform 110 may recommend alternate routes to vehicles that do not havean autonomous driving capability.

At step 214, vehicle management computing platform 110 may identify(e.g., by processor 111 executing vehicle management module 113)incentives for adjusting the autonomous mode and/or accepting arecommended alternate route for each corresponding vehicle. The vehiclemanagement computing platform 110 may offer any kind of incentive forthe vehicle. As an example, a vehicle management computing platform 110operated by an insurance company may offer discounts on insurancecoverage if the vehicle adjusts into or out of the autonomous modeand/or accepts an alternate route. As another example, a vehiclemanagement computing platform 110 operated by a toll authority mayprovide free or reduced access to toll roads, special lanes, or otherrestricted portions of roads. In addition to or as an alternative tofree or reduced goods and services, incentives may also includemodifications to traffic control, such as allocating autonomous-onlyroads or lanes, allowing a higher speed limit for a vehicle or a groupof vehicles, adjusting timing of traffic lights, and the like. Forexample, vehicle management computing platform 110 may cause adjustmentsto electronic traffic signs in order to convert certain lanes toautonomous-only lanes when above a certain percentage of vehicles aredriven in an autonomous mode. As another example, vehicle managementcomputing platform 110 may increase a speed limit (e.g., by causingadjustments to an electronic speed limit sign) when a traffic safetycharacteristic is optimized above a given threshold.

Vehicle management computing platform 110 may calculate the incentive tobe proportional to the benefit of the adjustment. For example, a driverwith a high driving score may be offered (e.g., by vehicle managementcomputing platform 110) a relatively large incentive to switch out ofautonomous mode when doing so would increase a desired safetycharacteristic. As another example, a vehicle may be offered (e.g., byvehicle management computing platform 110) a relatively large incentiveto accept an alternate route that will take significant additionaltravel time, or that is significantly safer. As yet another example, adriver may be offered (e.g., by vehicle management computing platform110) a relatively large incentive to switch to autonomous mode when thecorresponding vehicle information indicates a highly-rated autonomousdriving capability (e.g., due to advanced sensors or the like).

At step 215, vehicle management computing platform 110 may generate(e.g., by processor 111 executing vehicle management module 113) amessage for each of the vehicles corresponding to the autonomous modeadjustments and/or the route adjustments. Vehicle management computingplatform 110 may generate each message to include an indication of theincentive that will be received for making the adjustment. Vehiclemanagement computing platform 110 may further calculate an indication ofa length of time or distance during which the vehicle must continue withthe adjustment in order to receive the incentive, and include anindication of such length or distance in the message. For example, anincentive may be awarded when a vehicle stays in autonomous mode for acertain amount of time, or for a certain distance, or until a certaindestination is reached. Vehicle management computing platform 110 mayformat each message according to a format that is compatible with theautonomous vehicle control system 150, 160 or non-autonomous vehiclecontrol system 170 contained in each corresponding vehicle. At step 216,vehicle management computing platform 110 sends out each message to eachcorresponding vehicle. The messages may be transmitted via network 190to the one or more vehicles. Network 190 may include wired networks,cellular networks, satellite networks, and any other types of networks.

Referring to FIG. 2E, at step 217, a vehicle control system for eachvehicle (e.g., autonomous vehicle control system 150) may receive (e.g.,via communication interface 155) the message and output (e.g., viadisplay 156) a corresponding user interface containing information fromthe message to a display. In some embodiments, autonomous vehiclecontrol system 150 may display a user interface containing informationfrom the message immediately upon receipt of the message. In otherembodiments, autonomous vehicle control system 150 may wait to displaythe user interface until the user interface can be safely displayed. Forexample, autonomous vehicle control system 150 may wait until thevehicle is driving below a maximum speed to display the user interface.As another example, autonomous vehicle control system 150 may wait untilno other objects and/or vehicles are present within a certain distanceof the vehicle, or no other objects and/or vehicles are present in acertain area relative to the vehicle, such as a blind spot. As anotherexample, autonomous vehicle control system 150 may avoid displaying theuser interface when a vehicle is braking and/or turning. The autonomousvehicle control system 150 may evaluate whether the user interface canbe safely displayed based on data received from sensors 157 and/orsettings associated with vehicle control interfaces 159.

In some embodiments, a user interface containing information from amessage may be displayed upon a screen of the vehicle (e.g., display156). In other embodiments, the vehicle control system (e.g., autonomousvehicle control system 150) may transmit the message and/or userinterface to a device connected via local device interface 158. Forexample, autonomous vehicle control system 150 may transmit the messageand/or user interface via BLUETOOTH® for display by a smart device usedby the driver and/or passengers. In some embodiments, the vehiclecontrol system may select a smart device used by a passenger of thevehicle to display the user interface in order to avoid distracting thedriver.

Examples of user interfaces containing information from messages areillustrated at FIGS. 6-7. As shown at FIG. 6, the message may includeinformation indicating that a vehicle must be switched into anautonomous mode until it reaches its destination in order to receive aparticular incentive. The incentive may be access to a priority lane(e.g., of a toll road or highway). The displayed user interface 600 mayinclude options to accept or decline the incentive. In some embodiments,the vehicle control system (e.g., autonomous vehicle control system 150)may automatically decline the incentive after a certain amount of time.In these embodiments, the user interface may display a countdown or someother indication that the message is only valid for a limited time.

At step 218, when a driver or passenger of the vehicle indicatesacceptance of the incentive (e.g., by selecting an “accept” option ofuser interface 600, 700), autonomous vehicle control system 150 mayautomatically adjust the vehicle into an autonomous mode. Autonomousvehicle control system 150 may modify corresponding control settings invehicle control database 154 and/or adjust an autonomous mode viavehicle control interface 159. In some examples, the autonomous vehiclecontrol system 150 may be configured to (upon acceptance) accesspriority lanes, and adjust its settings and/or route accordingly.Similarly, for an incentive to adjust the vehicle out of an autonomousmode, acceptance of the incentive may cause the autonomous vehiclecontrol system 150 to automatically disengage the autonomous mode. Inthese situations, the autonomous vehicle control system 150 may display(e.g., in a user interface 600, 700) a countdown timer indicating thatthe autonomous mode will disengage in a certain amount of time.Additionally or alternatively, the autonomous vehicle control system 150may wait until it senses the driver's hands on the steering wheel (e.g.,via one of sensors 157) to disengage the autonomous mode.

As shown at FIG. 7, the user interface 700 may indicate an alternateroute and a corresponding incentive. Upon acceptance of the incentive,autonomous vehicle control system 150 may adjust a route of the vehicleand begin following the alternate route. For a non-autonomous vehiclecontrol system 170, accepting the incentive may cause non-autonomousvehicle control system 170 to display directions for following thealternate route (e.g., replacing user interface 700 with a navigationdisplay).

In some embodiments, vehicle management computing platform 110 may causethe incentive to be awarded upon acceptance of multiple adjustments. Forexample, an incentive may be conditional upon adjusting an autonomousmode as well as accepting an alternate route. Accordingly, accepting anincentive may cause the vehicle control system to adjust multiplecontrol settings.

In some embodiments, autonomous vehicle control system 150 mayautomatically accept the instructions contained in messages receivedfrom vehicle management computing platform 110. In this way, vehiclemanagement computing platform 110 may control and/or switch anautonomous vehicle in which autonomous vehicle control system 150 isinstalled into an autonomous mode (or non-autonomous mode) without inputfrom and/or action by a user of autonomous vehicle control system 150 ora passenger in the autonomous vehicle in which autonomous vehiclecontrol system 150 is installed. Accordingly, autonomous vehicle controlsystem 150 may adjust one or more settings without displaying a userinterface or receiving a user's acceptance of an incentive. In someembodiments, autonomous vehicle control system 150 may still display auser interface (e.g., one of user interfaces 600, 700) indicating anadjustment to one or more settings without providing an option todecline or accept the adjustment. In some embodiments, the messagereceived by autonomous vehicle control system 150 may cause autonomousvehicle control system 150 to adjust one or more settings withoutreceiving any incentive.

At step 219, the vehicle management computing platform 110 may continueto receive (e.g., via communications interface 115) vehicle guidancedata from autonomous vehicle control system 150 after adjustment of theone or more control settings by the autonomous vehicle control system150. The vehicle guidance data received at step 219 may include anotification that the driver has accepted the incentive. Such vehicleguidance data may be used by vehicle management computing platform 110to verify that the vehicle continues to comply with the conditions ofthe incentive (e.g., that a driver did not adjust back into/out of anautonomous mode or select a different route after accepting theincentive). For a non-autonomous vehicle control system 170, the vehicleguidance data may be further used by vehicle management computingplatform 110 to ensure that the driver is following the alternate routeindicated by the message.

Based on the vehicle guidance data from the one or more vehicles thatreceived messages from vehicle management computing platform 110,vehicle management computing platform 110 may identify (e.g., byprocessor 111 executing vehicle management module 113) additionalincentives to send to one or more of vehicles that received previousmessages and/or other vehicles of the evaluation group. For example,vehicle management computing platform 110 may send a message containinga second offer of a larger incentive to a vehicle that declined aprevious incentive. Additionally or alternatively, vehicle managementcomputing platform 110 may send messages containing incentives tovehicles that did not previously receive messages. Accordingly, vehiclemanagement computing platform 110 may send successive rounds of messagesin order to iteratively optimize a traffic characteristic.

At step 220, vehicle management computing platform 110 causes theincentive to be awarded based on verification of acceptance and/orcompliance received in vehicle guidance data at step 219. In someembodiments, partial incentives may be awarded for partial compliance.For example, if a driver accepts an incentive to switch into anautonomous mode, but later switches back out of the autonomous mode, aportion of the incentive may be awarded based on, for example, a time ordistance traveled in compliance with the incentive. As another example,a driver that accepts an incentive to take a first route, but latertakes a second route, may receive a partial award based on the portionof the first route followed.

Vehicle management computing platform 110 may loop back to or repeat anystep at any time. In some embodiments, vehicle management computingplatform 110 may periodically re-define an evaluation group at step 205,and send out additional messages in order to optimize a trafficcharacteristic for the re-defined evaluation group. Vehicle managementcomputing platform 110 may continue to receive vehicle guidance datathroughout the process and adjust the process according to the receivedvehicle guidance data. For example, when received vehicle guidance datacontains an indication that one or more vehicles is stuck in a trafficjam, had an accident, or has changed routes, vehicle managementcomputing platform 110 may define new evaluation groups at step 205,update road conditions information at steps 206-207, identify a newnumber of vehicles in autonomous mode in step 208, recalculate a newtarget number of ideal vehicles in autonomous mode in step 209, etc.

FIG. 8 depicts an illustrative method for controlling groups ofautonomous vehicles to optimize traffic characteristics in accordancewith one or more example embodiments. At step 805, an autonomous vehiclemanagement computing platform may receive vehicle guidance data from aplurality of vehicles having an autonomous mode. At step 810, theautonomous vehicle management computing platform may identify, based onthe vehicle guidance data, an actual number of vehicles currentlyoperating in the autonomous mode. At step 815, the autonomous vehiclemanagement computing platform may identify a target number of vehiclescurrently operating in a non-autonomous mode to switch to the autonomousmode. At step 820, the autonomous vehicle management computing platformmay, in response to identifying the target number, generate a firstmessage instructing a first vehicle of the plurality of vehicles topresent a first incentive to switch to the autonomous mode. At step 825,the autonomous vehicle management computing platform may send the firstmessage instructing the first vehicle to present the first incentive toswitch to the autonomous mode. At step 830, the autonomous vehiclemanagement computing platform may receive a notification from the firstvehicle indicating acceptance of the first incentive. At step 835, theautonomous vehicle management computing platform may, in response to thenotification, cause the first incentive to be awarded to a driver of thefirst vehicle.

One or more aspects of the disclosure may be embodied in computer-usabledata or computer-executable instructions, such as in one or more programmodules, executed by one or more computers or other devices to performthe operations described herein. Generally, program modules includeroutines, programs, objects, components, data structures, and the likethat perform particular tasks or implement particular abstract datatypes when executed by one or more processors in a computer or otherdata processing device. The computer-executable instructions may bestored as computer-readable instructions on a computer-readable mediumsuch as a hard disk, optical disk, removable storage media, solid-statememory, RAM, and the like. The functionality of the program modules maybe combined or distributed as desired in various embodiments. Inaddition, the functionality may be embodied in whole or in part infirmware or hardware equivalents, such as integrated circuits,application-specific integrated circuits (ASICs), field programmablegate arrays (FPGA), and the like. Particular data structures may be usedto more effectively implement one or more aspects of the disclosure, andsuch data structures are contemplated to be within the scope of computerexecutable instructions and computer-usable data described herein.

Various aspects described herein may be embodied as a method, anapparatus, or as one or more computer-readable media storingcomputer-executable instructions. Accordingly, those aspects may takethe form of an entirely hardware embodiment, an entirely softwareembodiment, an entirely firmware embodiment, or an embodiment combiningsoftware, hardware, and firmware aspects in any combination. Inaddition, various signals representing data or events as describedherein may be transferred between a source and a destination in the formof light or electromagnetic waves traveling through signal-conductingmedia such as metal wires, optical fibers, or wireless transmissionmedia (e.g., air or space). In general, the one or morecomputer-readable media may be and/or include one or more non-transitorycomputer-readable media.

As described herein, the various methods and acts may be operativeacross one or more computing servers and one or more networks. Thefunctionality may be distributed in any manner, or may be located in asingle computing device (e.g., a server, a client computer, and thelike). For example, in alternative embodiments, one or more of thecomputer systems discussed above may be combined into a single computersystem, and the various functions of each computer system may beperformed by the single computer system. In such arrangements, anyand/or all of the above-discussed communications between computersystems may correspond to data being accessed, moved, modified, updated,and/or otherwise used by the single computer system. Additionally oralternatively, one or more of the computing platforms discussed abovemay be implemented in one or more virtual machines that are provided byone or more physical computing devices. In such arrangements, thevarious functions of each computing platform may be performed by the oneor more virtual machines, and any and/or all of the above-discussedcommunications between computing platforms may correspond to data beingaccessed, moved, modified, updated, and/or otherwise used by the one ormore virtual machines.

Aspects of the disclosure have been described in terms of illustrativeembodiments thereof. Numerous other embodiments, modifications, andvariations within the scope and spirit of the appended claims will occurto persons of ordinary skill in the art from a review of thisdisclosure. For example, one or more of the steps depicted in theillustrative figures may be performed in other than the recited order,and one or more depicted steps may be optional in accordance withaspects of the disclosure.

What is claimed is:
 1. A method comprising: at an autonomous vehiclemanagement computing platform comprising at least one processor, memory,and a communication interface: receiving, by the at least one processor,via the communication interface, vehicle guidance data from a pluralityof vehicles having an autonomous mode; identifying, by the at least oneprocessor, based on the vehicle guidance data, an actual number ofvehicles currently operating in the autonomous mode; identifying, by theat least one processor, a target number of vehicles currently operatingin a non-autonomous mode to switch to the autonomous mode; in responseto identifying the target number, generating, by the at least oneprocessor, a first message instructing a first vehicle of the pluralityof vehicles to present a first incentive to switch to the autonomousmode; sending, by the at least one processor, via the communicationinterface, the first message instructing the first vehicle to presentthe first incentive to switch to the autonomous mode; receiving, by theat least one processor, via the communication interface, a notificationfrom the first vehicle indicating acceptance of the first incentive; andin response to receiving the notification, causing, by the at least oneprocessor, the first incentive to be awarded to a driver of the firstvehicle.
 2. The method of claim 1, further comprising, at the autonomousvehicle management computing platform, generating, by the at least oneprocessor, a second message instructing a second vehicle of theplurality of vehicles to present a second incentive to switch out of theautonomous mode.
 3. The method of claim 1, further comprising, at theautonomous vehicle management computing platform, generating, by the atleast one processor, a third message instructing a third vehicle topresent a third incentive to follow an alternate route.
 4. The method ofclaim 3, wherein the third vehicle is a non-autonomous vehicle.
 5. Themethod of claim 3, further comprising, at the autonomous vehiclemanagement computing platform, causing, by the at least one processor, aportion of the third incentive to be awarded based on an indication thatthe third vehicle followed a portion of the alternate route.
 6. Themethod of claim 1, wherein identifying the target number of vehiclescurrently operating in the non-autonomous mode to switch to theautonomous mode comprises identifying the target number of vehiclesbased on the actual number of vehicles currently operating in autonomousmode.
 7. The method of claim 1, wherein identifying the target number ofvehicles currently operating in the non-autonomous mode to switch to theautonomous mode comprises identifying the target number of vehiclesbased on driver information corresponding to one or more drivers of theplurality of vehicles.
 8. The method of claim 1, wherein identifying thetarget number of vehicles currently operating in the non-autonomous modeto switch to the autonomous mode comprises identifying the target numberof vehicles based on vehicle information corresponding to one or more ofthe plurality of vehicles.
 9. The method of claim 1, wherein identifyingthe target number of vehicles currently operating in the non-autonomousmode to switch to the autonomous mode comprises identifying the targetnumber of vehicles based on road conditions corresponding to one or moreroads associated with the plurality of vehicles.
 10. The method of claim1, wherein generating the first message instructing the first vehicle ofthe plurality of vehicles to present the first incentive to switch tothe autonomous mode comprises selecting the first incentive based on oneor more of a driver score associated with the driver of the firstvehicle and a vehicle score associated with the first vehicle.
 11. Acomputing platform comprising: at least one processor; a communicationinterface communicatively coupled to the at least one processor; andmemory storing computer-readable instructions that, when executed by theat least one processor, cause the computing platform to: receive, viathe communication interface, vehicle guidance data from a plurality ofvehicles having an autonomous mode; identify, based on the vehicleguidance data, an actual number of vehicles currently operating in theautonomous mode; identify a target number of vehicles currentlyoperating in a non-autonomous mode to switch to the autonomous mode; inresponse to identifying the target number, generate a first messageinstructing a first vehicle of the plurality of vehicles to present afirst incentive to switch to the autonomous mode; send the first messageinstructing the first vehicle to present the first incentive to switchto the autonomous mode; receive a notification from the first vehicleindicating acceptance of the first incentive; and in response to thereceived notification, cause the first incentive to be awarded to adriver of the first vehicle.
 12. The computing platform of claim 11, thememory storing further instructions that, when executed by the at leastone processor, cause the computing platform to: generate a secondmessage instructing a second vehicle of the plurality of vehicles topresent a second incentive to switch out of the autonomous mode.
 13. Thecomputing platform of claim 11, the memory storing further instructionsthat, when executed by the at least one processor, cause the computingplatform to: generate a third message instructing a third vehicle topresent a third incentive to follow an alternate route.
 14. Thecomputing platform of claim 13, wherein the third vehicle is anon-autonomous vehicle.
 15. The computing platform of claim 13, thememory storing further instructions that, when executed by the at leastone processor, cause the computing platform to: cause a portion of thethird incentive to be awarded based on an indication that the thirdvehicle followed a portion of the alternate route.
 16. The computingplatform of claim 11, wherein identifying the target number of vehiclescurrently operating in the non-autonomous mode to switch to theautonomous mode comprises identifying the target number of vehiclesbased on the actual number of vehicles currently operating in autonomousmode.
 17. The computing platform of claim 11, wherein identifying thetarget number of vehicles currently operating in the non-autonomous modeto switch to the autonomous mode comprises identifying the target numberof vehicles based on driver information corresponding to one or moredrivers of the plurality of vehicles.
 18. The computing platform ofclaim 11, wherein identifying the target number of vehicles currentlyoperating in the non-autonomous mode to switch to the autonomous modecomprises identifying the target number of vehicles based on vehicleinformation corresponding to one or more of the plurality of vehicles.19. The computing platform of claim 11, wherein identifying the targetnumber of vehicles currently operating in the non-autonomous mode toswitch to the autonomous mode comprises identifying the target number ofvehicles based on road conditions corresponding to one or more roadsassociated with the plurality of vehicles.
 20. One or morenon-transitory computer-readable media storing instructions that, whenexecuted by a computing platform comprising at least one processor,memory, and a communication interface, cause the computing platform to:receive, via the communication interface, vehicle guidance data from aplurality of vehicles having an autonomous mode; identify, based on thevehicle guidance data, an actual number of vehicles currently operatingin the autonomous mode; identify a target number of vehicles currentlyoperating in a non-autonomous mode to switch to the autonomous mode; inresponse to identifying the target number, generate a first messageinstructing a first vehicle of the plurality of vehicles to present afirst incentive to switch to the autonomous mode; send the first messageinstructing the first vehicle to present the first incentive to switchto the autonomous mode; receive a notification from the first vehicleindicating acceptance of the first incentive; and in response to thereceived notification, cause the first incentive to be awarded to adriver of the first vehicle.